JP5718683B2 - Recorder and moving average calculation method of recorder - Google Patents

Description

  The present invention relates to a recorder and a moving average calculation method for the recorder.

  Conventionally, a thermal power plant generates high-temperature and high-pressure steam with a boiler, rotates a turbine with the steam, and operates a generator connected to the turbine to generate power. The steam used to rotate the turbine in power generation is cooled by cooling water and reused. Since this cooling water is required in large quantities, seawater is usually used, flows from the sea into the cooling water channel, is used for cooling the steam, and then flows out to the sea.

  By the way, when the cooling water is used for cooling the steam, it becomes a high temperature, and if it flows out to the sea in a high temperature state, there is a possibility that the temperature of the sea water is increased and the environment is affected. Therefore, considering the impact on the environment, after the cooling water is used for steam cooling, the water temperature at the time of spilling into the sea is recorded and monitored by a recorder in order to manage the temperature so that it does not exceed the regulated value. Has been.

  As such a recorder, it periodically captures data from a plurality of channels, outputs a plurality of channel processing units, and selectively captures a plurality of data output from the plurality of channel processing units. There has been proposed a recorder including a plurality of block processing units that output block signals that have been subjected to predetermined processing by a program, and a recording processing unit that performs recording processing of block signals output from the plurality of block processing units (patent) Reference 1).

According to this recorder, a block signal obtained by selectively processing a plurality of data periodically captured by a plurality of channel processing units in a plurality of block processing units is output, and this block signal is recorded by the recording processing unit. it can.
Thus, for example, in a thermal power plant, the temperature of seawater flowing into the cooling water channel from the sea and the temperature of sea water flowing out of the cooling water channel into the sea are periodically taken, and a process for calculating the temperature difference between them is performed. This temperature difference can be recorded.

JP-A-61-31917

  By the way, in recent years, in a thermal power plant, the temperature difference between the temperature of seawater flowing into the cooling water channel from the sea and the temperature of sea water flowing out of the cooling water channel into the sea is not a temperature difference at a certain time but a plurality of time points. Monitoring is required with a moving average value that is the average of the temperature differences at.

Usually, in order to calculate the moving average value, a recorder is provided with a timer, and a predetermined interval is measured by this timer, and the data taken in by the channel processing unit (temperature and cooling of the seawater flowing into the cooling water channel from the sea) It is determined whether the temperature of the seawater flowing out from the waterway into the sea) is the data captured at this predetermined interval, and the data determined to have been captured at the predetermined interval and the number of such data are totaled, and the total value of the data A new program is needed to divide by the number of data.
Therefore, when the moving average value is calculated by the recorder, it is necessary to perform a mechanical modification such as newly providing a timer, and a new information for collecting and calculating information corresponding to a predetermined interval measured by the timer. A program is required.

  An object of the present invention is to provide a recorder having a configuration for periodically collecting data and capable of easily recording a moving average value with a certain reliability without providing a timer.

  (1) A plurality of input processing units that perform a process of capturing a plurality of types of input signals from a plurality of input units at a predetermined cycle and converting the plurality of types of input signals into a plurality of types of data, respectively, and the plurality of input processes A calculation unit that calculates a calculation value at the predetermined cycle based on a predetermined type of data among the plurality of types of data converted by the unit, the plurality of types of data converted by the plurality of input processing units, and the calculation unit And a recording unit that records each of the calculation values calculated in step (b), and the calculation unit includes a calculation storage unit that stores a predetermined number of the calculation values calculated in the predetermined cycle, and stores the calculation values in the calculation storage unit. A moving average value is calculated by dividing the total of the predetermined number of the calculated values by the predetermined number, and the recording unit records the moving average value.

  According to the invention of (1), the plurality of input processing units perform a process of capturing a plurality of types of input signals from the plurality of input units at a predetermined cycle and converting the plurality of types of input signals into a plurality of types of data, respectively. The calculation unit calculates a calculation value at a predetermined cycle based on a predetermined type of data among a plurality of types of data converted by the plurality of input processing units, and the recording unit converts the plurality of data converted by the plurality of input processing units. Each type of data and calculation value calculated by the calculation unit is recorded. The calculation unit has a calculation storage unit that stores a predetermined number of calculation values calculated at a predetermined cycle, and moves by dividing the total of the predetermined number of calculation values stored in the calculation storage unit by the predetermined number. The average value is calculated, and the recording unit records this moving average value.

As a result, a calculated value is calculated based on a predetermined type of data among a plurality of types of data obtained by converting the captured input signal at a predetermined cycle, and a predetermined number of the calculated values are stored. Then, the moving average value is calculated by dividing the total by a predetermined number, and this moving average value can be recorded.
Therefore, the moving average corresponding to the target time can be recorded with a certain level of reliability only by setting a predetermined number corresponding to the target time in accordance with a predetermined cycle in which the input processing unit takes in the input signal.
Therefore, a recorder having a configuration for periodically collecting data can provide a recorder that can easily record a moving average value with a certain reliability without providing a timer.

  (2) The recorder according to (1), wherein the calculation unit calculates the calculation value and the moving average value continuously at the predetermined period in a predetermined period.

According to the invention of (2), when the input processing unit has a performance of capturing an input signal every 30 seconds, for example, as a predetermined cycle, and the calculation unit continuously calculates a calculation value every 30 seconds, By setting the predetermined number to “120”, it is possible to calculate and record a moving average value for approximately one hour (30 seconds × 120 times).
Therefore, a recorder having a configuration for periodically collecting data can provide a recorder that can easily record a moving average value with a certain reliability without providing a timer.

(3) The calculation unit calculates the calculation value at the predetermined period in each of a plurality of periods, and the calculation storage unit stores the predetermined number by combining the calculation values calculated in the plurality of periods. The recorder according to (1), characterized in that:

  According to the invention of (3), for example, when the setting of the recorder is changed, even if there is a period in which the input signal is not taken in by the input processing unit, in the period before and after the period in which the interruption occurred, It is possible to calculate and record the moving average value by combining the calculated values based on the predetermined type of data obtained by converting the input signal that has been taken into a predetermined number. Therefore, it is possible to calculate and record the moving average value during the period corresponding to the time when the input signal is actually captured without measuring by the timer.

  (4) An input processing step of capturing a plurality of types of input signals from a plurality of input units at a predetermined cycle and converting the plurality of types of input signals into a plurality of types of data, respectively, and the plurality of types converted in the input processing step The calculation step for calculating the calculation value at the predetermined cycle based on the predetermined type of data among the data, the plurality of types of data converted in the input processing step, and the calculation value calculated in the calculation step are recorded respectively. Recording step, and the calculation step stores a predetermined number of the calculation values calculated at the predetermined cycle, and a total of the predetermined number of the calculation values stored in the calculation storage step. A moving average value calculating step of calculating a moving average value by dividing the predetermined value by the predetermined number, and the recording step records the moving average value. Average calculation method.

  According to the invention of (4), the same effect as that of the invention of (1) is produced.

  According to the present invention, it is possible to provide a recorder that can easily record a moving average value with a certain reliability without providing a timer in a recorder having a configuration for periodically collecting data.

It is a figure which shows the function structure of the recorder which concerns on embodiment of this invention. 6 is a timing chart illustrating timings at which the pulse generator according to the embodiment of the present invention transmits a clock signal in a normal mode. It is a timing chart which shows the timing which the pulse generation part which concerns on embodiment of this invention transmits a clock signal in sampling interruption mode. It is a flowchart explaining the operation | movement which calculates and records the moving average of the recorder which concerns on this embodiment.

  Embodiments of the present invention will be described below in detail with reference to the drawings. In the following description of the embodiments, the same constituent elements are denoted by the same reference numerals, and the description thereof is omitted or simplified.

[Functional structure of recorder 1]
FIG. 1 is a diagram showing a functional configuration of a recorder 1 according to an embodiment of the present invention.
The recorder 1 according to the present embodiment is a recorder that records the state of cooling water for cooling power generation equipment in a power plant. The cooling water in the present embodiment is seawater drawn from the sea, and flows out into the sea after cooling the power generation equipment.
The recorder 1 according to the present embodiment includes the inflow seawater temperature of seawater drawn from the sea, the outflow seawater temperature of seawater flowing out to the sea, the pH (pH) of seawater outflowing into the sea, and the residual chlorine of seawater outflowing into the sea. Record the temperature difference obtained by subtracting the inflow seawater temperature from the concentration, outflow seawater temperature, and the moving average of this temperature difference.

  The recorder 1 includes an input processing unit 10, a calculation unit 20, a recording unit 30, a mode switching unit 40, and a pulse generation unit 50. The recorder 1 also includes an inflow seawater temperature sensor 110 that measures the inflow seawater temperature, an outflow seawater temperature sensor 120 that measures the outflow seawater temperature, a pH sensor 130 that measures the pH of the seawater that flows into the sea, Is connected to a residual chlorine sensor 140 that measures the residual chlorine concentration of the seawater flowing into the seawater.

The input processing unit 10 includes a first input processing unit 11, a second input processing unit 12, a third input processing unit 13, and a fourth input processing unit 14.
When the first input processing unit 11 is connected to the inflow seawater temperature sensor 110 and receives a clock signal transmitted from the pulse generation unit 50 at a predetermined cycle (for example, approximately every 30 seconds, approximately every 20 seconds), The input signal of the inflow seawater temperature detected by the inflow seawater temperature sensor 110 is captured, and the input signal of the inflow seawater temperature is converted into data indicating the inflow seawater temperature (A / D conversion). Data shown is transmitted to the recording unit 30 and the calculation unit 20.

  That is, the first input processing unit 11 continuously from the pulse generator 50 at one predetermined cycle (for example, every 30 seconds) or a plurality of different predetermined cycles (for example, approximately every 30 seconds, approximately 20 The clock signal is received every second), and when this clock signal is received, the input signal of the inflow seawater temperature is taken and the input signal of the inflow seawater temperature is converted into data indicating the inflow seawater temperature (A / D conversion) The data which shows this inflow seawater temperature is transmitted to the recording part 30 and the calculating part 20. FIG.

  When the second input processing unit 12 is connected to the outflow seawater temperature sensor 120 and receives a clock signal transmitted from the pulse generation unit 50 at a predetermined cycle (for example, approximately every 30 seconds, approximately every 20 seconds), The input signal of the outflow seawater temperature detected by the outflow seawater temperature sensor 120 is captured, and the input signal of the outflow seawater temperature is converted into data indicating the outflow seawater temperature (A / D conversion). Data shown is transmitted to the recording unit 30 and the calculation unit 20.

  That is, the second input processing unit 12 continuously from the pulse generation unit 50 at one predetermined cycle (for example, approximately every 30 seconds) or a plurality of different predetermined cycles (for example, approximately every 30 seconds, approximately The clock signal is received every 20 seconds), and when this clock signal is received, an input signal of the outflow seawater temperature is taken, and the input signal of the outflow seawater temperature is converted into data indicating the outflow seawater temperature, Data indicating the outflow seawater temperature is transmitted to the recording unit 30 and the calculation unit 20.

  The third input processing unit 13 is connected to the pH sensor 130 and detected by the pH sensor 130 when receiving a clock signal transmitted from the pulse generation unit 50 at a predetermined cycle (for example, approximately every 30 seconds). A process for converting the pH input signal into data indicating the pH (A / D conversion) is performed, and the data indicating the pH is transmitted to the recording unit 30.

  The fourth input processing unit 14 is connected to the residual chlorine sensor 140 and is detected by the residual chlorine sensor 140 when receiving a clock signal transmitted from the pulse generation unit 50 at a predetermined cycle (for example, approximately every 30 seconds). The input signal of the residual chlorine concentration is taken in, the input signal of the residual chlorine concentration is converted into data indicating the residual chlorine concentration (A / D conversion), and the data indicating the residual chlorine concentration is stored in the recording unit 30. Send.

  Further, the first input processing unit 11, the second input processing unit 12, the third input processing unit 13, and the fourth input processing unit 14 each have a case where the data obtained by converting the input signal exceeds a predetermined reference value set in advance. Then, an alarm unit (not shown) (for example, a speaker, a lamp, etc.) is operated. The first input processing unit 11, the second input processing unit 12, the third input processing unit 13, and the fourth input processing unit 14 are each based on data obtained by converting the input signal, and display devices (not shown) (for example, A value based on the data is displayed on a liquid crystal, LED, or the like.

The calculation unit 20 includes a temperature difference calculation unit 21, a calculation storage unit 22, and a temperature difference moving average calculation unit 23.
The temperature difference calculation unit 21 is transmitted from the second input processing unit 12 when receiving a clock signal transmitted from the pulse generation unit 50 at a predetermined cycle (for example, approximately every 30 seconds, approximately every 20 seconds). The data indicating the inflow seawater temperature transmitted from the first input processing unit 11 is subtracted from the data indicating the outflow seawater temperature, the data indicating the temperature difference is calculated, and the data indicating the temperature difference is stored in the calculation storage unit 22. And transmits it to the recording unit 30.

In addition, the temperature difference calculation unit 21 is continuously supplied from the pulse generation unit 50 at one predetermined cycle (for example, approximately every 30 seconds) or a plurality of predetermined cycles (for example, approximately every 30 seconds, approximately 20 seconds). When the clock signal is received, the data indicating the temperature difference is calculated, and the data indicating the temperature difference is stored in the arithmetic storage unit 22 and transmitted to the recording unit 30.
Further, the temperature difference calculation unit 21 has a plurality of periods (for example, a first period of about 30 minutes and a second period of about 30 minutes after a predetermined interval after the first period). When the clock signal is received from the pulse generator 50 at a predetermined cycle, data indicating the temperature difference is calculated for each period, and the data indicating the temperature difference is stored in the arithmetic storage unit 22 and the recording unit 30. Send to.

  The calculation storage unit 22 stores data indicating the temperature difference calculated by the temperature difference calculation unit 21 for a predetermined number of times set in advance (for example, 120 times). The calculation storage unit 22 clears data indicating the oldest temperature difference by storing data indicating a new temperature difference. In addition, when the recorder 1 is turned off, the calculation storage unit 22 clears storage of data indicating a temperature difference.

  The temperature difference moving average calculation unit 23 is stored in the calculation storage unit 22 when receiving a clock signal transmitted from the pulse generation unit 50 at a predetermined cycle (for example, approximately every 30 seconds, approximately every 20 seconds). A moving average is calculated by calculating data indicating a total value of data indicating a temperature difference for a predetermined number of times (for example, 120 times) and dividing the data indicating the total value by a predetermined number of times (for example, 120). Data indicating the value is calculated, and data indicating the moving average value is transmitted to the recording unit 30.

  That is, the temperature difference moving average calculating unit 23 continuously or continuously from the pulse generator 50 at one predetermined cycle (for example, every 30 seconds) or a plurality of predetermined cycles (for example, approximately every 30 seconds, approximately 20 seconds). The clock signal is received every second), and when the clock signal is received, data indicating the moving average value is calculated, and the data indicating the moving average value is transmitted to the recording unit 30.

  In addition, the temperature difference moving average calculation unit 23 stores data indicating a temperature difference for a predetermined number of times (for example, 120 times) set in advance in the calculation storage unit 22 (for example, the power source of the recorder 1 is When the data indicating the temperature difference for a predetermined number of times has not been calculated, the data indicating the total value of the data indicating the temperature difference stored in the calculation storage unit 22 is calculated, and this total value is indicated. Data indicating the moving average value is calculated by dividing the data by the number of data indicating the stored temperature difference, and the data indicating the moving average value is transmitted to the recording unit 30.

The recording unit 30 includes an inflow seawater temperature recording unit 31, an outflow seawater temperature recording unit 32, a pH recording unit 33, a residual chlorine recording unit 34, a temperature difference recording unit 35, a temperature difference moving average recording unit 36, Is provided.
The inflow seawater temperature recording unit 31 is connected to the first input processing unit 11 and is based on the inflow seawater temperature data transmitted from the first input processing unit 11 at a timing when the inflow seawater temperature data is transmitted. The inflow seawater temperature is recorded on the medium (for example, recording paper).

  The outflow seawater temperature recording unit 32 is connected to the second input processing unit 12 and is based on the outflow seawater temperature data transmitted from the second input processing unit 12 at a timing when the outflow seawater temperature data is transmitted. The outflow seawater temperature is recorded on the medium (for example, recording paper).

  The pH recording unit 33 is connected to the third input processing unit 13, and based on the pH data transmitted from the third input processing unit 13, a predetermined medium (for example, a recording medium) at the timing when the pH data is transmitted. Record the pH on the paper.

  The residual chlorine recording unit 34 is connected to the fourth input processing unit 14, and based on the residual chlorine concentration data transmitted from the fourth input processing unit 14, at a timing when the residual chlorine concentration data is transmitted, Record the residual chlorine concentration on a medium (for example, recording paper).

  The temperature difference recording unit 35 is connected to the temperature difference calculating unit 21, and based on the temperature difference data transmitted from the temperature difference calculating unit 21, at a timing when the temperature difference data is transmitted, a predetermined medium (for example, Record the temperature difference on the recording paper.

  The temperature difference moving average recording unit 36 is connected to the temperature difference moving average calculating unit 23, and based on the temperature difference moving average value data transmitted from the temperature difference moving average calculating unit 23, the data of the temperature difference moving average value is stored. At the transmitted timing, the temperature difference moving average value is recorded on a predetermined medium (for example, recording paper).

The mode switching unit 40 switches the operation mode of the recorder 1.
The operation mode of the recorder 1 in this embodiment includes a normal mode and a sampling interruption mode.
The normal mode is a mode in which a temperature difference obtained by subtracting the inflow seawater temperature from the outflow seawater temperature and a moving average value of the temperature difference are continuously recorded in one predetermined cycle (for example, every 30 seconds).
The sampling interruption mode is a mode in which the setting of the recorder 1 is changed, and is a mode in which no clock signal is transmitted from the pulse generation unit 50 and the input processing unit 10, the calculation unit 20, and the recording unit 30 do not operate.

The mode switching unit 40 includes a mode switching input unit 41 and a mode switching control unit 42.
The mode switching input unit 41 is operated by the administrator of the recorder 1. The administrator operates the mode switching input unit 41 to select either the normal mode or the sampling interruption mode.

  The mode switching control unit 42 transmits mode data corresponding to either the normal mode or the sampling interruption mode selected by the mode switching input unit 41 to the pulse generating unit 50. Specifically, the mode switching control unit 42 transmits normal mode data to the pulse generation unit 50 when the normal mode is selected, and sampling stop mode data when the sampling interruption mode is selected.

The pulse generation unit 50 sends the input processing unit 10 and the calculation unit 20 to the input processing unit 10 and the calculation unit 20 in a predetermined cycle (for example, approximately every 30 seconds, approximately every 20 seconds) according to the type of mode data transmitted from the mode switching control unit 42. Send a clock signal.
The pulse generator 50 will be described in detail with reference to FIGS.
FIG. 2 is a timing chart showing the timing at which the pulse generator 50 transmits a clock signal in the normal mode.
FIG. 3 is a timing chart showing the timing at which the pulse generator 50 transmits a clock signal in the sampling interruption mode.

  The pulse generator 50 includes channels (ch) 1, ch2, ch3, ch4, ch5, and ch6, and transmits a clock signal in order from these six channels in a predetermined sampling period a (for example, approximately 5 seconds). . 2 and 3, off in each channel indicates a state in which no clock signal is transmitted, and on indicates that a clock signal is transmitted at each timing. Moreover, the notation of x in FIG. 3 indicates that the connection is released.

  As shown in FIG. 2, the pulse generation unit 50 sends ch1 to the first input processing unit 11 at the timing when the type of mode data transmitted from the mode switching control unit 42 (see FIG. 1) is switched to the normal mode. Connected, ch2 connected to the second input processor 12, ch3 connected to the third input processor 13, ch4 connected to the fourth input processor 14, ch5 connected to the temperature difference calculator 21, ch6 is connected to the temperature difference moving average calculation unit 23. The pulse generation unit 50 performs a predetermined sampling period a from ch1 to the first input processing unit 11, then from ch2 to the second input processing unit 12, next from ch3 to the third input processing unit 13, and then to ch4. To the fourth input processing unit 14, next ch 5 to the temperature difference calculating unit 21, next ch 6 to the temperature difference moving average calculating unit 23, and then again from ch 1 in order.

  As a result, the temperature difference moving average calculation cycle b, which is a cycle for transmitting a clock signal to the temperature difference moving average calculation unit 23, is a value obtained by multiplying the sampling cycle a (for example, approximately 5 seconds) by 6 that is the number of channels (for example , Approximately 30 seconds). Further, the temperature difference moving average calculation cycle c of a predetermined number (for example, 120 times) is a value obtained by multiplying the temperature difference moving average calculation cycle b (for example, approximately 30 seconds) by a predetermined number of times (for example, 120 times) (for example, Approximately 1 hour).

  Next, as shown in FIG. 3, the pulse generation unit 50 receives the ch1 and the first input at the timing when the type of mode data transmitted from the mode switching control unit 42 (see FIG. 1) is switched to the sampling interruption mode. The connection with the processing unit 11 is released, the connection between the ch2 and the second input processing unit 12 is released, the connection between the ch3 and the third input processing unit 13 is released, and the ch4 and the fourth input processing unit 14 are connected. The connection is released, the connection between ch5 and the temperature difference calculation unit 21 is released, and the connection between ch6 and the temperature difference moving average calculation unit 23 is released. Accordingly, the first input processing unit 11, the second input processing unit 12, the third input processing unit 13, the fourth input processing unit 14, the temperature difference calculation unit 21, and the temperature difference moving average calculation unit 23 receive the clock signal. Does not work because it does not.

  The pulse generation unit 50 has the ch1 to ch6, the first input processing unit 11, the second input processing unit 12, and the timing when the type of mode data transmitted from the mode switching control unit 42 (see FIG. 1) is switched. The connection with the third input processing unit 13, the fourth input processing unit 14, the temperature difference calculation unit 21, and the temperature difference moving average calculation unit 23 is switched.

[Operation to calculate and record moving average of recorder 1]
Next, the operation of calculating and recording the moving average of the recorder 1 in the normal mode will be described.
FIG. 4 is a flowchart for explaining the operation of calculating and recording the moving average of the recorder 1 according to this embodiment.

  In step S1, an input signal of inflow seawater temperature is captured. In this process, the first input processing unit 11 (see FIG. 1) receives a clock signal from the ch1 (FIG. 2) of the pulse generation unit 50 at a predetermined period, takes in an input signal of the inflow seawater temperature, The process which converts the temperature input signal into the data which shows inflow seawater temperature is performed, and the data which show this inflow seawater temperature are transmitted to the calculating part 20 (refer FIG. 1).

  In step S2, an input signal of the outflow seawater temperature is captured. In this process, the second input processing unit 12 (see FIG. 1) receives a clock signal at a predetermined cycle from ch2 (FIG. 2) of the pulse generation unit 50, takes in an input signal of the outflow seawater temperature, The process which converts the input signal of temperature into the data which show an outflow seawater temperature is performed, and the data which show this outflow seawater temperature are transmitted to the calculating part 20 (refer FIG. 1).

  In step S3, a process for calculating a temperature difference is performed. In this process, when the temperature difference calculation unit 21 (see FIG. 1) receives a clock signal transmitted at a predetermined cycle from ch5 or ch3 (FIG. 2) of the pulse generation unit 50, the second input is performed in step S2. The data indicating the inflow seawater temperature transmitted from the first input processing unit 11 (see FIG. 1) in step S1 is subtracted from the data indicating the outflow seawater temperature transmitted from the processing unit 12 (see FIG. 1), and the temperature Data indicating the difference is calculated, and the data indicating the temperature difference is stored in the operation storage unit 22 (see FIG. 1).

  In step S4, processing is performed to determine whether the number of data indicating the temperature difference is stored a predetermined number of times. In this process, the temperature difference moving average calculation unit 23 (see FIG. 1) determines whether or not data indicating a predetermined number of temperature differences is stored in the calculation storage unit 22 (see FIG. 1). To do. If the temperature difference moving average calculation unit 23 determines that the data indicating the temperature difference for the predetermined number of times is stored, the process proceeds to step S5, and the data indicating the temperature difference for the predetermined number of times is not stored. If so, the process proceeds to step S6.

  In step S5, a process of calculating a temperature difference moving average value for a predetermined number of times is performed. In this process, when the temperature difference moving average calculation unit 23 (see FIG. 1) receives a clock signal transmitted at a predetermined cycle from ch6 or ch4 (FIG. 2) of the pulse generation unit 50, the calculation storage unit 22 The data indicating the total value of the data indicating the temperature difference for the predetermined number of times stored in (see FIG. 1) is calculated, and the moving average value is calculated by dividing the data indicating the total value by the predetermined number of times set in advance. The data shown is calculated, and the data showing the moving average value is transmitted to the recording unit 30 (see FIG. 1).

  In step S6, a process of calculating a temperature difference moving average value with the stored number is performed. In this process, when the temperature difference moving average calculation unit 23 (see FIG. 1) receives a clock signal transmitted at a predetermined cycle from ch6 or ch4 (FIG. 2) of the pulse generation unit 50, the calculation storage unit 22 The data indicating the total value of the data indicating the temperature difference stored in (see FIG. 1) is calculated, and the data indicating the total value is moved by dividing by the number of data indicating the stored temperature difference. Data indicating the average value is calculated, and the data indicating the moving average value is transmitted to the recording unit 30 (see FIG. 1).

In step S7, a process of recording the temperature difference moving average value is performed. In this process, the temperature difference moving average recording unit 36 (see FIG. 1) is based on the data of the temperature difference moving average value transmitted from the temperature difference moving average calculating unit 23 (see FIG. 1) in step S5 or step S6. The temperature difference moving average value is recorded on a predetermined medium (for example, recording paper) at the timing when the temperature difference moving average value data is transmitted.
After this process, the recorder 1 returns the process to step S1.

According to this embodiment, there are the following effects.
According to this embodiment, the 1st input processing part 11, the 2nd input processing part 12, the 3rd input processing part 13, and the 4th input processing part 14 are the inflow seawater temperature sensor 110 and the outflow seawater temperature sensor with a predetermined cycle. 120, input signals of inflow seawater temperature, outflow seawater temperature, pH and residual chlorine concentration are taken from pH sensor 130 and residual chlorine sensor 140, and the input signals indicate inflow seawater temperature, outflow seawater temperature, pH and residual chlorine concentration, respectively. The calculation part 20 performs the process converted into data, the inflow seawater temperature and the outflow seawater temperature which were converted in the 1st input process part 11, the 2nd input process part 12, the 3rd input process part 13, and the 4th input process part 14 Calculate the temperature difference by subtracting the inflow seawater temperature from the outflow seawater temperature in a predetermined cycle based on the data indicating the inflow seawater temperature and outflow seawater temperature among the data indicating the pH and residual chlorine concentration. The recording unit 30 indicates inflow seawater temperature, outflow seawater temperature, pH, and residual chlorine concentration converted by the first input processing unit 11, the second input processing unit 12, the third input processing unit 13, and the fourth input processing unit 14. The data and the data indicating the temperature difference calculated by the calculation unit 20 are recorded. The calculation unit 20 has a calculation storage unit 22 that stores a predetermined number of data indicating the temperature difference, and divides the total of the data indicating the predetermined number of temperature differences stored in the calculation storage unit 22 by the predetermined number. Thus, the moving average value is calculated, and the recording unit 30 records the moving average value.

Thereby, in a predetermined cycle, based on the data indicating the inflow seawater temperature and the outflow seawater temperature among the data indicating the inflow seawater temperature, the outflow seawater temperature, the pH, and the residual chlorine concentration converted from the input signal captured in the predetermined cycle. Calculate the temperature difference by subtracting the inflow seawater temperature from the outflow seawater temperature, store a predetermined number of data indicating the temperature difference, and divide the total of the data indicating the temperature difference stored by the predetermined number by the predetermined number The value can be calculated and this moving average value can be recorded.
Therefore, the moving average corresponding to the target time is fixed by simply setting a predetermined number according to the target time in accordance with a predetermined cycle in which the first input processing unit 11 and the second input processing unit 12 take in the input signal. Can be recorded with high reliability.

In addition, the calculation unit 20 calculates data indicating a temperature difference and a moving average value continuously in a predetermined cycle in the normal mode.
As a result, the first input processing unit 11 and the second input processing unit 12 have a performance of capturing an input signal, for example, every 30 seconds as a predetermined cycle, and the calculation unit 20 continuously calculates a calculation value every 30 seconds. When the predetermined number is set to “120”, a moving average value can be calculated and recorded approximately every hour (30 seconds × 120 times).

In addition, when the normal mode is divided by the sampling interruption mode, the calculation unit 20 calculates data indicating a temperature difference at each predetermined cycle in the divided normal mode, and the calculation storage unit 22 is in the normal mode. A predetermined number of data indicating the calculated temperature difference is stored together.
Thereby, for example, when the setting of the recorder 1 is changed, even if there is a period in which the input signal capture by the first input processing unit 11 and the second input processing unit 12 is interrupted, In the period before and after, the moving average value can be calculated and recorded by combining the data indicating the temperature difference based on the data indicating the outflow seawater temperature and the inflow seawater temperature obtained by converting the captured input signal. Therefore, it is possible to calculate and record the moving average value during the period corresponding to the time when the input signal is actually captured without measuring by the timer.

  As mentioned above, although embodiment of this invention was described, this invention is not restricted to embodiment mentioned above. The effects described in the embodiments of the present invention are only the most preferable effects resulting from the present invention, and the effects of the present invention are limited to those described in the embodiments of the present invention. is not.

DESCRIPTION OF SYMBOLS 1 Recorder 11 1st input process part 12 2nd input process part 13 3rd input process part 14 4th input process part 20 Calculation part 30 Recording part 22 Calculation storage part 110 Inflow seawater temperature sensor 120 Outflow seawater temperature sensor 130 pH sensor 140 Residual chlorine sensor

Claims (4)

A plurality of input processing units that perform a process of capturing a plurality of types of input signals from a plurality of input units at a predetermined period and converting the plurality of types of input signals into a plurality of types of data,
A calculation unit that calculates a calculation value at the predetermined cycle based on a predetermined type of data among the plurality of types of data converted by the plurality of input processing units;
A recording unit for recording the plurality of types of data converted by the plurality of input processing units and the calculation value calculated by the calculation unit;
With
The computing unit is
A calculation storage unit that stores a predetermined number of the calculation values calculated at the predetermined period
A moving average value is calculated by dividing the total of the predetermined number of the calculation values stored in the calculation storage unit by the predetermined number,
The recording unit records the moving average value ,
The calculation unit calculates the calculation value at the predetermined period in a plurality of periods,
The calculation storage unit stores the predetermined number of the calculation values calculated in the plurality of periods together .   The recorder according to claim 1, wherein the calculation unit calculates the calculation value and the moving average value continuously at the predetermined period in a predetermined period. An input processing step of capturing a plurality of types of input signals from a plurality of input units at a predetermined period and converting the plurality of types of input signals into a plurality of types of data, respectively,
A calculation step of calculating a calculation value in the predetermined cycle based on a predetermined type of data among the plurality of types of data converted in the input processing step;
A recording step for recording the plurality of types of data converted in the input processing step and the calculation value calculated in the calculation step;
With
The calculation step includes
A calculation storage step of storing a predetermined number of the calculation values calculated at the predetermined period;
A moving average value calculating step of calculating a moving average value by dividing the total of the predetermined number of the calculation values stored in the calculation storage step by the predetermined number;
The recording step records the moving average value ,
The calculation step calculates the calculation value at the predetermined period in each of a plurality of periods,
In the calculation storage step, the predetermined number of the calculation values calculated in the plurality of periods are combined and stored, and the moving average calculation method for the recorder is characterized in that 4. The moving average calculation method for a recorder according to claim 3, wherein in the calculation step, the calculation value and the moving average value are continuously calculated at the predetermined period in a predetermined period.

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